A method of processing a circuit design in a circuit design tool includes: identifying selection of a parameterized core to be instantiated in a description of the circuit design managed by the circuit design tool and configured for implementation in target hardware; processing a configuration file for the parameterized core to select a set of parameter values from a plurality of sets of parameter values dynamically based at least in part on the target hardware; creating an instance of the parameterized core in the circuit design having the selected set of parameter values; and implementing the circuit design for the target hardware.
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1. A method of processing a circuit design in a circuit design tool, comprising:
identifying selection of a parameterized core to be instantiated in a description of the circuit design managed by the circuit design tool and configured for implementation in target hardware;
processing a configuration file for the parameterized core to select a set of parameter values from a plurality of sets of parameter values dynamically based at least in part on the target hardware;
creating an instance of the parameterized core in the circuit design having the selected set of parameter values; and
implementing the circuit design for the target hardware.
16. A computer system including a circuit design tool executing therein configured to process a circuit design, comprising:
a design entry module configured to:
identify selection of a parameterized core to be instantiated in a description of the circuit design managed by the circuit design tool and configured for implementation in target hardware;
process a configuration file for the parameterized core to select a set of parameter values from a plurality of sets of parameter values dynamically based at least in part on the target hardware; and
create an instance of the parameterized core in the circuit design having the selected set of parameter values; and
an implementation module configured to implement the circuit design for the target hardware.
11. A non-transitory computer readable medium comprising instructions which, when executed in a computer system, cause the computer system to carry out a method of processing a circuit design in a circuit design tool, comprising:
identifying selection of a parameterized core to be instantiated in a description of the circuit design managed by the circuit design tool and configured for implementation in target hardware;
processing a configuration file for the parameterized core to select a set of parameter values from a plurality of sets of parameter values dynamically based at least in part on the target hardware;
creating an instance of the parameterized core in the circuit design having the selected set of parameter values; and
implementing the circuit design for the target hardware.
2. The method of
displaying a graphical user interface (GUI) of the circuit design tool to present a representation of at least one predefined configuration of the parameterized core; and
obtaining the configuration file in response to selection of a predefined configuration of the parameterized core through the GUI.
3. The method of
the configuration file comprises a script; and
the processing comprises executing the script within the circuit design tool using at least one attribute defined by the circuit design tool for the circuit design as a parametric input.
4. The method of
6. The method of
the configuration file comprises a description of the plurality of sets of parameter values; and
the processing comprises parsing the description of the plurality of sets of parameter values in the circuit design tool to obtain the set of parameter values based on at least one attribute defined by the circuit design tool for the circuit design.
7. The method of
the configuration file comprises object code; and
the processing comprises dynamically linking the object code with the circuit design tool and executing the object code using at least one attribute defined by the circuit design tool for the circuit design as a parametric input.
8. The method of
the set of parameter values comprises a subset of parameter values for the parameterized core; and
the creating the instance comprises generating values for parameters undefined in the set of parameter values based on parameters defined in the set of parameter values.
9. The method of
modifying a value of each of at least one parameter of the parameterized core; and
generating a new configuration file for the parameterized code having a new set of parameter values in response to the modifying.
10. The method of
the target hardware comprises a programmable IC; and
the implementing comprises generating a physical implementation of the circuit design for configuring the programmable IC.
12. The non-transitory computer readable medium of
the configuration file comprises a script; and
the processing comprises executing the script within the circuit design tool using at least one attribute defined by the circuit design tool for the circuit design as a parametric input.
13. The non-transitory computer readable medium of
14. The non-transitory computer readable medium of
the configuration file comprises a description of the plurality of sets of parameter values; and
the processing comprises parsing the description of the plurality of sets of parameter values in the circuit design tool to obtain the set of parameter values based on at least one attribute defined by the circuit design tool for the circuit design.
15. The non-transitory computer readable medium of
the configuration file comprises object code; and
the processing comprises dynamically linking the object code with the circuit design tool and executing the object code using at least one attribute defined by the circuit design tool for the circuit design as a parametric input.
17. The computer system of
the configuration file comprises a script; and
the design entry module executes the script within the circuit design tool using at least one attribute defined by the circuit design tool for the circuit design as a parametric input.
18. The computer system of
19. The computer system of
the configuration file comprises a description of the plurality of sets of parameter values; and
the design entry module parses the description of the plurality of sets of parameter values in the circuit design tool to obtain the set of parameter values based on at least one attribute defined by the circuit design tool for the circuit design.
20. The computer system of
the configuration file comprises object code; and
the design entry module dynamically links the object code with the circuit design tool and executes the object code using at least one attribute defined by the circuit design tool for the circuit design as a parametric input.
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The present disclosure generally relates to electronic circuit design and, in particular, to circuit design with predefined configuration of parameterized cores.
Circuit designs for integrated circuits (ICs) can be generated using a variety of techniques. In some examples, designers can write register-transfer level (RTL) code program-language code, or a combination thereof to design a circuit for implementation in a target IC device. The target IC device can be a programmable IC, such as a field programmable gate array (FPGA), a mask-programmable IC, such as an application specific integrated circuit (ASIC), or the like. During circuit design, designers can make use of pre-designed circuits available from logic libraries provided for a particular target IC device. Such pre-design circuits are referred to as “Intellectual Property (IP) cores” or just “cores”. The cores are generally tested and debugged blocks of logic that can be used for specific purposes to simplify implementation of a circuit in a particular target IC device.
Some cores are static. A designer can select a static core, such as a counter, from a library for use in a given circuit design. Although the counter may not be customizable for a particular designer's needs, several counters may be available in the library and a designer can select the appropriate counter for a particular design. Other cores are parameterized cores. Parameterized cores can be specifically configured for a designer's particular needs by defining parameter values. The parameter values translate into RTL parameters, which customize the logic and functionality of the core. For example, a designer can select a parameterized counter from a library having a width parameter. When the designer creates an instance of the counter, the designer can define a value for the width parameter (e.g., a 4-bit counter, an 8-bit counter, etc.).
Some parameterized cores can include a large number of parameters, some of which are dependent on others. In some cases, a designer may not be familiar with all the parameters of a given core, particularly when some cores define parameters differently than other cores. A designer may find it cumbersome to modify each and every parameter of a parameterized core. For some parameterized cores, a designer needs to understand the purpose of several parameters, which may not have a standard definition, and be able to identify a good combination of parameter values. A designer may have to resort to testing of different sets of parameter values, particularly when some parameters are dependent on other parameters, before finding an appropriate configuration for the particular circuit design and target IC device.
Circuit design with predefined configuration of parameterized cores is described. In an example implementation, a method of processing a circuit design in a circuit design tool includes: identifying selection of a parameterized core to be instantiated in a description of the circuit design managed by the circuit design tool and configured for implementation in target hardware; processing a configuration file for the parameterized core to select a set of parameter values from a plurality of sets of parameter values dynamically based at least in part on the target hardware; creating an instance of the parameterized core in the circuit design having the selected set of parameter values; and implementing the circuit design for the target hardware.
In another example implementation, a non-transitory computer readable medium comprising instructions which, when executed in a computer system, cause the computer system to carry out a method of processing a circuit design in a circuit design tool. The method comprises: identifying selection of a parameterized core to be instantiated in a description of the circuit design managed by the circuit design tool and configured for implementation in target hardware; processing a configuration file for the parameterized core to select a set of parameter values from a plurality of sets of parameter values dynamically based at least in part on the target hardware; creating an instance of the parameterized core in the circuit design having the selected set of parameter values; and implementing the circuit design for the target hardware.
In yet another example implementation, a computer system including a circuit design tool executing therein configured to process a circuit design includes a design entry module and an implementation module. The design entry module is configured to: identify selection of a parameterized core to be instantiated in a description of the circuit design managed by the circuit design tool and configured for implementation in target hardware; process a configuration file for the parameterized core to select a set of parameter values from a plurality of sets of parameter values dynamically based at least in part on the target hardware; and create an instance of the parameterized core in the circuit design having the selected set of parameter values. The implementation module is configured to implement the circuit design for the target hardware.
So that the manner in which the above recited features can be understood in detail, a more particular description, briefly summarized above, may be had by reference to example implementations, some of which are illustrated in the appended drawings. It is to be noted, however, that the appended drawings illustrate only typical example implementations and are therefore not to be considered limiting.
To facilitate understanding, identical reference numerals have been used, where possible, to designate identical elements that are common to the figures. It is contemplated that elements of one example may be beneficially incorporated in other examples.
Circuit design with predefined configuration of parameterized cores is described. In an example implementation, a circuit design tool identifies selection of a parameterized core to be instantiated in a description of the circuit design configured for implementation in target hardware. The target hardware includes an integrated circuit (IC), such as an FPGA, ASIC, or the like. The parameterized core can be selected from a library of “intellectual property (IP)” cores. An IP core (also referred to herein as a “core”) is a description of a logic block having pre-designed functionality. End users can create instances of cores in their circuit designs. A parameterized core includes parameters that can be configured to customize the logic and functionality of the core. Some or all parameters of a parameterized core can have default values, which are typically generic and not specific to the target hardware.
In example implementations described herein, a parameterized core can be associated with one or more configuration files that include one or more predefined configurations (also referred to as a “preset configurations”) of parameters. Each preset configuration includes a set of parameter values for the parameterized core. For example, different preset configurations can be specified for the parameterized core for different target hardware. The circuit design tool processes configuration file(s) for the parameterized core to select a set of parameter values from potential sets of parameter values dynamically based at least in part on the target hardware. The circuit design tool can then create an instance of the parameterized core in the circuit design having the selected set of parameter values. The circuit design can then be implemented for the target hardware.
Preset configurations for parameterized cores provide ease of use for the end user through a faster method of core configuration without the need of changing every parameter value manually. A given parameterized core can include hundreds of parameters, which have to be understood by the end user and configured correctly for the target hardware in order for the core to function. Core providers can establish preset configurations for parameterized cores, which can be tested a priori for different target hardware so that they are guaranteed to work when used by the end user. In some examples, a preset configuration can dynamically select among different parameter value sets based on project properties defined for the circuit design within the circuit design tool. Thus, a given present configuration can adapt to the current project (e.g., adapt to particular attributes of target hardware). In some examples, the preset configurations are extensible by the end user. The end user can modify one or more parameter values and then establish a new preset configuration for a parameterized core. The new preset configuration can be entirely new, or based on a previous preset configuration. These and other aspects are described further below.
Turning now to the figures,
In an example implementation, the IC 102 comprises an FPGA.
In some FPGAs, each programmable tile can include at least one programmable interconnect element (“INT”) 211 having connections to input and output terminals 220 of a programmable logic element within the same tile, as shown by examples included at the top of
In an example implementation, a CLB 202 can include a configurable logic element (“CLE”) 212 that can be programmed to implement user logic plus a single programmable interconnect element (“INT”) 211. A BRAM 203 can include a BRAM logic element (“BRL”) 213 in addition to one or more programmable interconnect elements. Typically, the number of interconnect elements included in a tile depends on the height of the tile. In the pictured example, a BRAM tile has the same height as five CLBs, but other numbers (e.g., four) can also be used. A DSP tile 206 can include a DSP logic element (“DSPL”) 214 in addition to an appropriate number of programmable interconnect elements. An IOB 204 can include, for example, two instances of an input/output logic element (“IOL”) 215 in addition to one instance of the programmable interconnect element 211. As will be clear to those of skill in the art, the actual I/O pads connected, for example, to the I/O logic element 215 typically are not confined to the area of the input/output logic element 215.
In the pictured example, a horizontal area near the center of the die (shown in
Some FPGAs utilizing the architecture illustrated in
Note that
In general, the circuit design system 300 generates a description of the circuit design, which is processed into a physical implementation (“implementation”) of the circuit design for particular target hardware. The circuit design system 300 can process the description of the circuit design through various intermediate transformations to produce the implementation of the circuit design, including a functional description and a logical description. The implementation of the circuit design can be formatted and loaded into a programmable IC to produce a physical circuit, or used to produce physical masks to form an ASIC. Thus, the circuit design system 300 transforms an abstract representation of the circuit design (the description) into a physical representation of the circuit design (the implementation) that can be formatted to realize a physical circuit in an IC.
A user interacts with the circuit design tool 302 to produce project files 316 and circuit design files 318. The project files 316 include one or more files specifying project settings for each circuit design. For example, the project files 316 can specify attributes for target hardware of a circuit design, such as a type of IC in the target hardware, a model of the IC, a clock speed of the IC, a number of 10 ports of the IC, and the like. The circuit design files 318 include one or more files specifying a description of each circuit design. The description can be divided into different abstractions as discussed above, such as a functional description and a logical description. The circuit design tool 302 processes the circuit design files 318 to generate implementation files 328. The implementation files 328 include one or more files specifying a physical implementation of each circuit design, such as bitstream files for programmable ICs or mask files for ASICs.
The design entry module 304 is configured to generate a functional description of the circuit design in response to user input through the GUI 314. The functional description can include descriptions for a plurality of circuit components, such as flip-flops, memories, logic gates, processors, and the like, coupled together by connections (referred to as “nets” or “signals”). The functional description can include a register transfer level (RTL) description specified using a circuit design language, such as a hardware description language (HDL), and/or specified schematically. The functional description can include a high-level model description specified using a program language, such as C, C++, JAVA, or the like, and/or specified schematically. The functional description can include a combination of RTL and high-level model descriptions. The functional description can be stored in one or more of the circuit design files 318. The GUI 314 can include a graphic interface through which an end user connects symbols and blocks representing various components to produce a schematic of the circuit design. The GUI 314 can include a text interface through which a user writes HDL/program language code. The GUI 314 can employ a combination of schematic and text-based entry.
The synthesis module 306 is configured to produce a logical description of the circuit design from the functional description. The logical description of the circuit design includes a logical representation of the circuit design in terms of specific logic elements. For example, the synthesis tool 212 can perform “technology mapping” that transforms generic circuit elements into technology-specific circuit elements. For example, the logical description can include a representation of the circuit design in terms of specific logic elements optimized to the architecture of a programmable IC, such as lookup tables (LUTs), carry logic, IO buffers, and like technology-specific components. In an example, the logical description includes a logical network list (“netlist”) supported by an IC of the target hardware. The logical description can be stored in one or more of the circuit design files 318.
The implementation module 308 is configured to produce an implementation of the circuit design from the logical description. The implementation of the circuit design is a physical representation of the circuit design for implementation in target hardware. For example, the implementation module 308 can map, place, and route the logical description for implementation in a programmable IC of the target hardware. The physical implementation can include a bitstream for configuring the programmable IC with a circuit specified by the circuit design. In another example, the implementation module 308 can place and route the logical description for implementation in an ASIC or the like. The implementation can include a set of mask definitions for manufacturing an ASIC with the circuit specified by the circuit design. The implementation can be stored in one or more of the implementation files 328.
The circuit design tool 302 can access a library 330 having a plurality of cores 324. Some or all of the cores 324 are parameterized. The design entry module 304, through the GUI 314, can provide an interface for an end user to create instances of one or more of the cores 324 in the functional description. Each parameterized core has at least one configuration file associated therewith (“core preset files 320”). Each of the core preset files 320 defines one or more preset configurations of a given parameterized core through the specification of one or more sets of parameter values. The design entry module 304 identifies selection of a parameterized core by the end user to be instantiated in the description of the circuit design. In response, the design entry module 304 identifies associated core preset file(s) for the parameterized core and presents representations of preset configuration(s) contained in the core preset file(s) to the end user through the GUI 314. When the end user selects a preset configuration, the design entry module 304 processes a respective core preset file, which sets the parameters of the parameterized core to the parameter values defined in the selected preset configuration. The design entry module 304 then creates an instance of the parameterized core having the parameter values of the selected preset configuration in the description of the circuit design.
In general, a given parameterized core can include a plurality of parameters, and a given preset configuration can define parameter values for one or more of the plurality of parameters. That is, a given preset configuration can define parameter values for all of the parameters of a parameterized core, or only a subset of the parameters of the parameterized core. Thus, in some cases, the parameterized core can include parameters undefined in a given preset configuration. The design entry module 304 can determine values of the undefined parameters when creating an instance of the parameterized core. For example, the design entry module 304 can assign default values to one or more undefined parameters. In another example, one or more undefined parameters may be dependent on parameters defined by a preset configuration and are assigned values based on values of associated defined parameters.
The page navigator view 406 includes a list of pages that display different data for the XXXX core. In the present example, the page navigator view 406 includes entries for a “block description”, a “configuration”, “I/O pins”, “clock configuration”, “DDR configuration”, and “interrupts” for the XXXX core. For example, the XXXX core can be a processing system core having microprocessor(s), memory, controller(s), peripheral(s), and the like. In the present example, the “configuration” page is selected, which shows a table of parameters, associated parameter values and descriptions for the XXXX core in the detail view 414. In particular, the detail view 414 includes a column 408 showing a list of parameters, a column 410 showing a list of parameter values, and a column 412 showing a list of parameter descriptions. The parameters in the column 408 are organized as a tree having parameter categories/subcategories and associated parameters. The present example shows nine parameters designated “parameter 1” through “parameter 9”, each having a respective “value 1” through “value 9” and a respective “description 1” through “description 9”. The GUI 400 is merely one example GUI for displaying parameters, values, and descriptions, and for allowing selection and saving of preset configurations for a parameterized core.
Returning to
A function 504, designated “isPresetApplicable( )”, operates to determine if the preset configuration is applicable to the current circuit design. In the present example, the “isPresetApplicable( )” function accesses a globally defined variable “boardName” that is an attribute of the target hardware generally identifying the target hardware. For example, the “boardName” variable can be defined in a project file for the circuit design. The “isPresetApplicable( )” function can control whether the preset configuration is presented to the end user as a selectable option for the given parameterized core.
A function 506, designated “applyPreset( )”, operates to return a set of parameter values for the preset configuration. In the present example, the “applyPreset( )” function returns a dictionary, where keys are parameters of the parameterized core and the values are parameter values. The function 506 defines a single set of parameter values 508, which is returned without considering any input. In the example, the function 506 returns parameter values for “parameter 1” through “parameter 4”. As noted above, the parameterized core may have more than four parameters. The parameters undefined in the set 508 can receive default values and/or values derived from the parameter values in the set 508 (e.g., dependent parameters).
Returning to
In another example, the core preset files 320 can include dynamic linked libraries (DLLs) 326. Each of the DLLs 326 comprises object code that can be dynamically linked with the object code of the design entry module 304 and executed to impart the same functionality of the script functions discussed above. For example, each of the DLLs 326 can specify set(s) of parameter values for a parameterized core. Each of the DLLs 326 can also specify other types of information related to the preset configuration, such as the information in the “getPresetInfo( )” function described above. Each of the DLLs 326 can also specify commands to implement dynamic behavior, as described above in the example script functions (e.g., commands to dynamically select a preset configuration from a plurality of preset configurations based on attribute(s) of the target hardware).
At step 608, the circuit design tool 302 processes the configuration file for the parameterized core to select a set of parameter values dynamically based at least in part on the target hardware. The step 608 can include steps 610-614. At step 610, the circuit design tool 302 executes a script using project property attribute(s) as parametric input (e.g., attributes of the target hardware). At optional step 612, the circuit design tool 302 parses a description of parameter value sets (e.g., a text file) based on project property attribute(s) (e.g., attributes of the target hardware). At optional step 614, the circuit design tool 302 dynamically links with object code and executes the object code using project property attribute(s) as parametric input (e.g., attributes of the target hardware).
At step 616, the circuit design tool 302 creates an instance of the parameterized core in the circuit design having the selected set of parameter values. The step 616 can include a step 618, where the circuit design tool generates values for parameters undefined in the selected set of parameter values. At optional step 620, the circuit design tool 302 can modify one or more parameter value(s) in response to input from an end user. At optional step 622, the circuit design tool 302 can generate a new preset configuration for the parameterized core in response to the modification of parameter(s). At step 624, the circuit design tool 302 implements the circuit design for target hardware.
The memory 708 may store all or portions of one or more programs and/or data to implement the systems and methods described herein. For example, the memory 708 can store programs for implementing the circuit design system 300 of
The various examples described herein may employ various computer-implemented operations involving data stored in computer systems. For example, these operations may require physical manipulation of physical quantities—usually, though not necessarily, these quantities may take the form of electrical or magnetic signals, where they or representations of them are capable of being stored, transferred, combined, compared, or otherwise manipulated. Further, such manipulations are often referred to in terms, such as producing, identifying, determining, or comparing. Any operations described herein that form part of one or more example implementations may be useful machine operations. In addition, one or more examples also relate to a device or an apparatus for performing these operations. The apparatus may be specially constructed for specific required purposes, or it may be a general purpose computer selectively activated or configured by a computer program stored in the computer. In particular, various general purpose machines may be used with computer programs written in accordance with the teachings herein, or it may be more convenient to construct a more specialized apparatus to perform the required operations.
The various examples described herein may be practiced with other computer system configurations including hand-held devices, microprocessor systems, microprocessor-based or programmable consumer electronics, minicomputers, mainframe computers, and the like.
One or more examples may be implemented as one or more computer programs or as one or more computer program modules embodied in one or more computer readable media. The term computer readable medium refers to any data storage device that can store data which can thereafter be input to a computer system—computer readable media may be based on any existing or subsequently developed technology for embodying computer programs in a manner that enables them to be read by a computer. Examples of a computer readable medium include a hard drive, network attached storage (NAS), read-only memory, random-access memory (e.g., a flash memory device), a Compact Disc (CD)-ROM, a CD-R, or a CD-RW, a DVD (Digital Versatile Disc), a magnetic tape, and other optical and non-optical data storage devices. The computer readable medium can also be distributed over a network coupled computer system so that the computer readable code is stored and executed in a distributed fashion.
While the foregoing is directed to specific examples, other and further examples may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.
Kumar, Prashanth, Nagpal, Sumit, Maguluri, Sreevidya
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